Impact of SiN Composition Variation on SANOS Memory Performance and Reliability Under nand (FN/FN) Operation

Abstract-Program/Erase (P/E) cycling endurance in poly-Si/Al 2 O 3 /SiN/SiO 2 /Si (SANOS) memories is systematically studied. Cycling-induced trap generation, memory window (MW) closure, and eventual stack breakdown are shown to be strongly influenced by the material composition of the silicon nitride (SiN) charge trap layer. P/E pulsewidth and amplitude, as well as starting program and erase flatband voltage (V FB ) levels (therefore the overall MW), are shown to uniquely impact stack degradation and breakdown. An electron-flux-driven anode hole generation model is proposed, and trap generation in both SiN and tunnel oxide are used to explain stack degradation and breakdown. This paper emphasizes the importance of SiN layer optimization for reliably sustaining large MW during P/E operation of SANOS memories.

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“…• C [28], [30]. Table I summarizes the device details with the flow ratios and measured refractive index (RI) of different gate stacks.…”

Section: Device Detailsmentioning

confidence: 99%

Study of P/E Cycling Endurance Induced Degradation in SANOS Memories Under NAND (FN/FN) Operation

Sandhya

Oak

Chattar

et al. 2010

IEEE Trans. Electron Devices

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“…This result also agreed with previous studies for a MONOS device with a Si rich nitride charge-trapping layer. (11,12) Furthermore, a much deeper negative-charge E TA was observed for O-MONOS with an oxy-nitride trapping layer than for STD-MONOS. This result also agreed with the previous study of a MONOS device with an oxy-nitride charge-trapping layer.…”

Section: Charge Loss Vs Annealing Temperaturementioning

confidence: 96%

“…For preirradiated S-MONOS, a larger negative-charge-loss with retention time was observed due to the relatively shallow negative-charge trap energy level (E TA ) originating from Si-H or Si dangling bonds, which causes significant thermal excitation of trapped negative charges to the nitride conduction band. (11,12) The result shows that high silicon composition ratio in the trapping nitride layer led to worse negative charge retention reliability characteristic of pre-irradiated S-MONOS. The figure shows that the trend in charge retention loss with time for S-MONOS after 10 Mrad gamma irradiation is exactly opposite to that before gamma irradiation.…”

Section: T Stability Vs Retention Timementioning

confidence: 98%

“…This result also agreed with the previous study for the Si-rich nitride chargetrapping layer in a MONOS device. (11,12) Relatively shallow negative-charge trap energy levels (E TA ) originating from Si-H or Si dangling bonds were observed for S-MONOS (compared to STD-MONOS). This result also agreed with previous studies for a MONOS device with a Si rich nitride charge-trapping layer.…”

Section: Charge Loss Vs Annealing Temperaturementioning

confidence: 99%

“…This result also agreed with the previous study of a MONOS device with an oxy-nitride charge-trapping layer. (11,12) …”

Section: Charge Loss Vs Annealing Temperaturementioning

confidence: 99%

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Charge Retention Improvement of Nonvolatile Radiation Sensor Using Metal–Oxide–Nitride–Oxide–Silicon with Si-Rich Nitride and Oxy-Nitride as Stack Charge-Trapping Layer

2016

Sensors and Materials

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Metal-oxide-nitride-oxide-silicon devices with Si-rich nitride and oxy-nitride as a bi-layer stack charge-trapping layer (hereafter STOB-MONOS) could be candidates for nonvolatile total ionizing dose (TID) radiation sensors. In the case of STOB-MONOS nonvolatile TID radiation sensors, gamma radiation induces a significant decrease in the threshold voltage V T , which is nearly 2 times larger than that of a standard MONOS device. The change in V T for STOB-MONOS after gamma irradiation also has a strong correlation to TID up to 10 Mrad gamma irradiation. The reliability characteristics of V T retention time before and after gamma irradiation for STOB-MONOS devices can be markedly improved and is nearly 12% better than that of a standard MONOS device. The STOB-MONOS device in this study has demonstrated the possibility of improved the feasibility of non-volatile high TID radiation sensing.

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Review of Semiconductor Flash Memory Devices for Material and Process Issues

et al. 2022

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Vertically integrated NAND (V‐NAND) flash memory is the main data storage in modern handheld electronic devices, widening its share even in the data centers where installation and operation costs are critical. While the conventional scaling rule has been applied down to the design rule of ≈15 nm (year 2013), the current method of increasing device density is stacking up layers. Currently, 176‐layer‐stacked V‐NAND flash memory is available on the market. Nonetheless, increasing the layers invokes several challenges, such as film stress management and deep contact hole etching. Also, there should be an upper bound for the attainable stacking layers (400–500) due to the total allowable chip thickness, which will be reached within 6–7 years. This review summarizes the current status and critical challenges of charge‐trap‐based flash memory devices, with a focus on the material (floating‐gate vs charge‐trap‐layer), array‐level circuit architecture (NOR vs NAND), physical integration structure (2D vs 3D), and cell‐level programming technique (single vs multiple levels). Current efforts to improve fabrication processes and device performances using new materials are also introduced. The review suggests directions for future storage devices based on the ionic mechanism, which may overcome the inherent problems of flash memory devices.

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Impact of SiN Composition Variation on SANOS Memory Performance and Reliability Under nand (FN/FN) Operation

Cited by 32 publications

References 37 publications

Study of P/E Cycling Endurance Induced Degradation in SANOS Memories Under NAND (FN/FN) Operation

Study of P/E Cycling Endurance Induced Degradation in SANOS Memories Under NAND (FN/FN) Operation

Charge Retention Improvement of Nonvolatile Radiation Sensor Using Metal–Oxide–Nitride–Oxide–Silicon with Si-Rich Nitride and Oxy-Nitride as Stack Charge-Trapping Layer

Review of Semiconductor Flash Memory Devices for Material and Process Issues

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Impact of SiN Composition Variation on SANOS Memory Performance and Reliability Under nand (FN/FN) Operation

Cited by 32 publications

References 37 publications

Study of P/E Cycling Endurance Induced Degradation in SANOS Memories Under NAND (FN/FN) Operation

Study of P/E Cycling Endurance Induced Degradation in SANOS Memories Under NAND (FN/FN) Operation

Charge Retention Improvement of Nonvolatile Radiation Sensor Using Metal&ndash;Oxide&ndash;Nitride&ndash;Oxide&ndash;Silicon with Si-Rich Nitride and Oxy-Nitride as Stack Charge-Trapping Layer

Review of Semiconductor Flash Memory Devices for Material and Process Issues

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Product

Resources

About

Charge Retention Improvement of Nonvolatile Radiation Sensor Using Metal–Oxide–Nitride–Oxide–Silicon with Si-Rich Nitride and Oxy-Nitride as Stack Charge-Trapping Layer